DE2634792B1 - Crosspoint tester for centrally controlled telephone exchange - closes line or column crosspoints simultaneously and forms test loop with others - Google Patents

Abstract

The crosspoint tester, for centrally-controlled telephone exchange, successively tests all crosspoints in a switching stage's group. All row or column crosspoints lying in the test loop within the switching group being tested are closed simultaneously. The remaining crosspoints in this group needed to form the test loop are then systematically closed one after another in a given order. After the crosspoints in this loop have been tested the crosspoints in another line of column are closed simultaneously and further crosspoints closed one after another as before so that untested crosspoints are now tested.

Description

According to a further embodiment of the invention, the test loop over several coupling stages and over

a connection coupler connected in parallel to the space coupler, the the transmitter and receiver of the automatic coupling network testing device to the appropriate Ends of the test loop, access to the coupling groups.

This reduces the route search and control effort for connections in the space coupler can also be used for interconnections in the interface coupler.

Even in such a case that outputs of a crosspoint column or crosspoint row are not connected, so can be done in a simple manner by means of the same test method, the successive testing of a crosspoint group of a switching stage a multi-level switching network.

Based on the F i g. 1 to 7 are some embodiments of the invention described. Only the details that are important for understanding are shown.

The F i g. 1 shows a simplified system overview; Fig.2 shows using an example, one that runs across all coupling stages and coupling groups Test loop; the F i g. 3 to 7 show different examples of the systematic Checking all crosspoints of a crosspoint group.

In FIG. 1 shows how the automatic switch tester AKP parallel to the space coupler PK access to the switching matrix groups KS 1 and KS2, which crosspoints of two coupling stages A and B or A 'and B' as well as to the switching matrix groups KS3 and KS4 of the switching stage C or C'hat. About crosspoints these switching matrix groups and switching stages will, as follows with reference to the others F i g. 2 to 5 is described, a test loop is set up over which measurements in the automatic switching network testing device AKP, the state of the device to be tested Crosspoint, that is, the test object is determined. To this test loop to be able to produce, there are two ways via the interface coupler AK to to switch through the actual connection coupling test device AKP, namely in such a way that that on one line a transmitter and on the other line a receiver in the test facility is switched on.

From the system overview in FIG. list shows that, for example Participant records TS, house records HS, official records AS and electoral acceptance records WAS all the same side of the switching matrix group KS1 for the purpose of switching through connections can be switched on.

This means that the present system is a so-called Reverse grouping acts. From the other figures it can be seen in which Way such connections over the switching matrix groups and switching stages and thus can be produced via the coupling groups. The network controller shown NST controls in a manner known per se via the group controls STI and ST2, the speech path through-connection in the coupling stages of the coupling network with the aid of the route search devices KFE and KUFE 'This network control also determines which test of the automatic Coupling network testing device is to be carried out from the resulting F i g. 1 is also still possible As already mentioned, it emerges that the connection coupler AK of the testing device AKP is connected in parallel to the space coupler. The operator station becomes the operator station via the station coupler Via a free place connection to the coupling network KN for the purpose of querying or switching turned on by calls. Due to the fact that the coupler AK of the test facility AKP is connected in parallel to the space coupler PK, the effort can be due to common Utilization of the switching means necessary for the connection both for the setting in the space coupler PK and in the interface coupler AK in the test facility as well as for the connection through-connection in the coupling network KN can be used jointly.

In FIG. 2 is the grouping of a switching network KN as Example shown, which both the division into different coupling levels A, B, C; d. H.

KVA, KVB, KVC, as well as the group division into coupling groups KG 1 to KG 16 can be recognized per coupling stage The participants are in the KVA coupling stage combined in groups and each have access to the next coupling stage KVB. The connection sets and transmissions are also in groups summarized.

From this Fig.2 it can also be seen that they are the transmitter S and the Receiver E of the automatic switching network testing device AKP in different Coupling groups of the switching stage KVA and also in different switching matrix groups KS 1 / KS2 are located. This is intended to allow the variation to be varied while maintaining it the greatest possible accessibility of crosspoints with as little change as possible the test paths are guaranteed.

In the example in Fig. 2, all should be marked with a strong cross Crosspoints be permanently connected, while in the switching matrix group KS 1 the Coupling stage KVA and there especially in coupling group KG 16 all coupling points checked should be.

This is done in the manner described below.

Without changing the test paths, tests can be carried out in all Coupling groups are made in which a coupling point for the formation of the shown Test loop is closed. In order to avoid double testing of groups, a corresponding marking of groups that have already been tested with a special bit in the test program be made.

In the embodiment described in Figure 2, it is assumed that all coupling groups of the various coupling stages have the same dimensions. This means, for example, that ten rows and eight columns are provided for each coupling group are.

If one considers the switching group accordingly in the switching matrix group KS1 KGO of the A-level, you can first of all see that the examination of a transfer of office, z. B. AU1, when switching on the automatic switching network testing device AKP the actuated coupling points (marked with a strong cross) of the coupling groups shown to a column line is possible if there is a coupling point in this column line is closed. If, for example, the trunk transfer AU1 is checked, the is To operate crosspoint 0 of column 0, which is indicated with a slash (Fig. 3).

On the other hand, the check of the crosspoints in the coupling group KG 16, all crosspoints in column 7 must first be closed and it is on the intermediate line ZL 7 via the other existing coupling groups to connect other coupling stages of the transmitter or receiver of the test device. Will the receiver is switched on on this column line, then on the other column line, in which a crosspoint is to be checked, to switch on a receiver. From the central Control device is now the successive opening and closing the crosspoints in the second column.

In Fig. 3 is an example of testing all crosspoints Coupling group KGO of the KVA level closing all coupling points in column 7 represented by crosses, while the crosspoint 00 of column 0 as the momentary DUT is shown and circled. To simplify the test procedure and to avoid unnecessary coupling in the other for the creation of the test loop used or not yet used coupling groups and coupling stages are always Within a coupling group, first all the coupling points of the successively one after the other Column 0 actuated in succession and the previously actuated in each case Contacts shared. For example, after checking contact 00 in the Column 0, contact 01 in column 0, then contact 02 in column 0, then the Contact 03 of column 0 etc. is checked by the contact to be tested closes and all other contacts are open. So then just come across this a contact a test circuit via the intermediate line ZL 0 and the closed Crosspoint, e.g. B. 12 of column 0 and 72 of column 7 to intermediate line ZL 7 conditions. If all crosspoints in column 0 have been checked, the next step is the Intermediate line ZL 1 occupied and all crosspoints of the column are sequentially 1 checked. So you move all intermediate lines 0 to 6 and thus all column lines and the crosspoints arranged therein.

You only have to change the occupied intermediate lines six times and thus only to make six switchovers in coupling group KG 0 (cf. F i g. 2). To check the crosspoints that are connected to the intermediate line ZL 7 in F i g. 3 are reached via another intermediate line in a column all crosspoints actuated and then successively one after the other in column 7 one after the other one crosspoint after the other closed. This is shown in FIG. 4 symbolic shown with the downward pointing arrow on the right side of the illustration. In the F i g. 3 to 6, the respective test sequences are symbolically indicated with I and II. II is the column-by-column test (column by column) and I is the line-by-line test Test (crosspoint by crosspoint).

There are no subscribers on the row lines, but rather transmissions or connection sets are switched on, this does not mean a change in the test procedure, because it does not matter whether participants or transmissions via the coupling group can be achieved. The exam then remains the same.

Based on the F i g. 5 describes how the test is carried out if Intermediate lines are not connected.

These unconnected intermediate lines are called stubs. In Fig. 5 three stubs STu are shown. In this case, all crosspoints are first of columns X to 7 checked in the same way as above with reference to the F i g. 3 and 4 is described.

Then the other crosspoints, their intermediate lines ZL 0 to ZL 3 are not connected, as shown in FIG. 6 is shown thereby checked that if the output is not connected, here z. B.

Intermediate line ZL 0, a crosspoint column in this column 0 a Crosspoint, e.g. B. 06 for the time of successive testing of the other crosspoints 01, 02, 03, 04, 05, 07, 08 of this column 0 is actuated and at the same time the crosspoint in the same line 06 is the same for the successive Check to be operated crosspoints of a column, z. B. 6, remains unactuated to to enable a test loop over two columns and an intermediate line. The unchecked crosspoints of row 6 and columns 0 to 3 are their intermediate lines are not connected are checked one after the other in a special cycle. For the production of the test loop are in this case three per coupling group Close crosspoints.

In this context it should be mentioned that a perfect Examination of all crosspoints necessary for the implementation of the successive examination of all Crosspoints of a coupling group are operated longer, that is, in the F i g. 3 to 7 are marked with a strong cross, must be functional and none May have an earth fault in order to be able to carry out the test. This arises but immediately when testing the first test item, because if on the first test item If an error is found, all crosspoints involved in this test are included should be checked as any of these crosspoints are the cause of the error detection can be. In order to determine whether this error occurs, for example in the column lies in which all crosspoints are actuated, it is simply sufficient to only use the column switch. It can thus be determined whether the crosspoints of the column or the test object is faulty. If it was a cross point in the column, the next test is with the greatest probability positive, that is, free of errors. In this case are then preferably to check all crosspoints of the column with the faulty contact, which in turn takes place in the manner as shown in FIG. 3 and 4 is. To this end, a preference may be given to examining the faulty column be carried out or the routine test can be waited for since the test of the individual crosspoints of the columns is going on very quickly anyway. Instead of of closing all crosspoints of a column can of course also all Crosspoints of a line are closed, as shown in FIG. 7 shown is. An intermediate line can then also be used for testing the DUT Line can be used. In this case, all crosspoints are then also first one line checked. Then the crosspoints of the next are checked Line checked and finally all crosspoints in the line in which the check was carried out has not yet taken place. This is done by changing the corresponding line, for which purpose only one coupling in a preceding coupling group is required. These The latter type of test is for testing the crosspoints in the coupling groups the C. coupling stages are most appropriate.

Finally it should be mentioned that the one shown in FIG Test path can also be run several times over the same coupling stages. Herewith can the necessary coupling can be further reduced, since in such a case still there are more testable coupling groups in the test loop.

Claims (4)

Claims: 1. Method for the systematic testing of crosspoints in multi-stage switching networks, preferably each switching stage in several Crosspoint groups is divided, as well as from decentralized facilities in centrally controlled Telecommunications, in particular telephone systems, with the help of central control and Storage devices in a specific, predetermined sequence, in that of the central Control a connection path from test equipment sending a test signal via Interface couplers and speech path crosspoints at various coupling levels and back is set up for test equipment receiving and evaluating the test signal, so that a respective test lies in a test loop, characterized in that that in the coupling point group to be tested (KGO in Fig. 2) of a coupling stage (KVA) all crosspoints of a column (e.g. 7) or row in the test loop are switched through at the same time, while to close the test loop in this crosspoint group (KGO) of the coupling stage to be tested (KVA) the remaining Crosspoints (in columns O to 6) one after the other systematically in predetermined Sequence (e.g. 00 to 09) are switched through and that when carried out in this way Testing of all crosspoints (columns 0 to 6) of the crosspoint group (KGO) in one other column (e.g. 6 in FIG. 4) or row all crosspoints (00 to 09) at the same time be switched through to then also the not yet checked crosspoints (the Column 7) one after the other in a predetermined order (00 to 09). 2. The method according to claim 1, characterized in that the closure of the test loop each via one leading to a column and one leading to a row Intermediate line is closed. 3. The method according to claim 1, characterized in that when not connected Output of a crosspoint column or row in this column or row a crosspoint for the time of the successive testing of the other crosspoints in this column or line is pressed and at the same time the one in the same line or column lying crosspoint of the crosspoints to be operated simultaneously in a column or line remains unactuated to create a real test loop over two columns and to enable a row or two row and a column intermediate line. 4. Circuit arrangement for performing the method according to a of claims 1 to 3, characterized in that the test loop over several Coupling stages and via a connection coupler connected in parallel to the space coupler (PK) (AK) leads, the transmitter and receiver of the automatic coupling testing device (AKP) switches on at the corresponding ends of the test loop, access to the switching matrix groups Has. The invention relates to a method for systematic testing of crosspoints in multi-stage switching matrices, preferably each Coupling stage vieder is divided into several crosspoint groups, as well as decentralized facilities in centrally controlled telecommunications, in particular telephone systems, with the help of central control and storage devices in a specific, predetermined sequence, in which a connection path from the central controller sends a test signal Test facilities via interface couplers at speech path coupling points of various Coupling stages and back to test equipment receiving and evaluating the test signal is set up so that a respective test object lies in a test loop. A systematic and successive check of crosspoints in multi-level Coupling matrices in centrally controlled telecommunications, in particular telephone systems, with the help of central control and storage devices of all crosspoints thereby bring about that successively different connection paths for the purpose of production a test loop are known. That for this successive examination of all crosspoints one after the other different paths are to be switched through via different crosspoints For example, see DT-OS 17 62 179. The object of the present invention is to successively To simplify checking all crosspoints of a crosspoint group of a switching stage and to standardize for all crosspoint groups of the same and different switching stages. This is achieved in that in the crosspoint group to be tested a coupling stage all coupling points in a column or in the test loop Line can be switched through at the same time while closing the test loop the remaining crosspoints in this crosspoint group of the switching stage to be tested are systematically switched through one after the other in a predetermined order and that with the test carried out in this way, all crosspoints of the crosspoint group then in another column or row all crosspoints are switched through at the same time to then also the not yet checked crosspoints one after the other in a predetermined Order to close. In this way, not only is a shorter test time achieved, because In any case, partial routes can remain, but it is also the contact load less than with known systems. There is also the option to use the the same interface of the test device to carry out the sentence test via the coupling matrix. It is also possible to test smaller functional units. According to a further embodiment of the invention, it is also possible to check those crosspoints that lie in rows or columns, their intermediate lines are not yet connected. This is achieved by the fact that when the Output of a crosspoint column or row in this column or row a crosspoint for the time of the successive testing of the other crosspoints in this column or line is pressed and at the same time the one in the same line or column lying crosspoint of the crosspoints to be operated simultaneously in a column or line remains unactuated to create a real test loop over two columns and to enable a row or two row and a column intermediate line.